Machine Intelligence on Wireless Edge Networks
This addresses latency and privacy issues for edge computing in wireless networks, representing a novel paradigm rather than an incremental improvement.
The paper tackles the problem of energy and delay in machine intelligence on edge devices by broadcasting model weights as RF waveforms for local analog computation in the radio receive chain, achieving reduced memory and conversion overhead while maintaining high accuracy in realistic scenarios.
Machine intelligence on edge devices enables low-latency processing and improved privacy, but is often limited by the energy and delay of moving and converting data. Current systems frequently avoid local model storage by sending queries to a server, incurring uplink cost, network latency, and privacy risk. We present the opposite approach: broadcasting model weights to clients that perform inference locally using in-physics computation inside the radio receive chain. A base station transmits weights as radio frequency (RF) waveforms; the client encodes activations onto the waveform and computes the result using existing mixer and filter stages, RF components already present in billions of edge devices such as cellphones, eliminating repeated signal conversions and extra hardware. Analysis shows that thermal noise and nonlinearity create an optimal energy window for accurate analog inner products. Hardware-tailored training through a differentiable RF chain preserves accuracy within this regime. Circuit-informed simulations, consistent with a companion experiment, demonstrate reduced memory and conversion overhead while maintaining high accuracy in realistic wireless edge scenarios.